Your search keyword '"Landín M"' showing total 15 results

1. Mineralized alginate hydrogels using marine carbonates for bone tissue engineering applications

Author

Diaz-Rodriguez, P., Garcia-Triñanes, P., Echezarreta López, M.M., Santoveña, A., and Landin, M.

Published

2018

2. Biomateriales en medicina regenerativa: del diseño a la aplicación

Author

Martínez-Borrajo, R., Diaz-Rodriguez, P., Santos-Rosales, V., López-Iglesias., C., Iglesias Mejuto, A., Gómez-Amoza, J.L., García-González, C.A., and Landín, M.

Abstract

La ingeniería de tejidos requiere del uso de biomateriales con requisitos específicos respecto a su estructura, composición, propiedades mecánicas y esterilidad. Además de su función como soporte mecánico para el desarrollo celular, estos materiales pueden tener prestaciones avanzadas a través de su carga con moléculas terapéuticas. desarrollo de nuevos métodos capaces de asegurar la esterilidad de los biomateriales manteniendo su estabilidad supone un gran avance para el campo de la ingeniería de tejidos. Del mismo modo, el desarrollo de biomateriales nanométricos para la liberación selectiva de fármacos tiene un elevado potencial en la regeneración de tejidos musculoesqueléticos.

Published

2020

3. Deciphering kiwifruit seed germination using neural network tools

Author

González-Puelles, J.E., primary, Landín, M., additional, Gallego, P.P., additional, and Barreal, M.E., additional

Published

2018

4. Controlled release of rAAV-2 viral vectors from alginate-poloxamer complex systems

Author

Rey-Rico, A, Diaz-Rodriguez, P, Madry, H, Landín, M, and Cucchiarini, M

Subjects

ddc: 610, viruses, technology, industry, and agriculture, Cartilage Repair, macromolecular substances, Gene Therapy, 610 Medical sciences, Medicine, rAAV Controlled Release

Abstract

Objectives: Inclusion of viral vectors in polymeric systems is an attractive approach to enhance their stability and efficacy and decrease potential neutralizing immune responses. We developed different alginate-poloxamer hydrogel structures to entrap and release rAAV vectors for the genetic modification[for full text, please go to the a.m. URL], Deutscher Kongress für Orthopädie und Unfallchirurgie (DKOU 2015)

Published

2015

5. Vancomycin-Loaded 3D-Printed Polylactic Acid-Hydroxyapatite Scaffolds for Bone Tissue Engineering.

Author

Pérez-Davila S, Potel-Alvarellos C, Carballo R, González-Rodríguez L, López-Álvarez M, Serra J, Díaz-Rodríguez P, Landín M, and González P

Abstract

The regeneration of bone remains one of the main challenges in the biomedical field, with the need to provide more personalized and multifunctional solutions. The other persistent challenge is related to the local prevention of infections after implantation surgery. To fulfill the first one and provide customized scaffolds with complex geometries, 3D printing is being investigated, with polylactic acid (PLA) as the biomaterial mostly used, given its thermoplastic properties. The 3D printing of PLA in combination with hydroxyapatite (HA) is also under research, to mimic the native mechanical and biological properties, providing more functional scaffolds. Finally, to fulfill the second one, antibacterial drugs locally incorporated into biodegradable scaffolds are also under investigation. This work aims to develop vancomycin-loaded 3D-printed PLA-HA scaffolds offering a dual functionality: local prevention of infections and personalized biodegradable scaffolds with osseointegrative properties. For this, the antibacterial drug vancomycin was incorporated into 3D-printed PLA-HA scaffolds using three loading methodologies: (1) dip coating, (2) drop coating, and (3) direct incorporation in the 3D printing with PLA and HA. A systematic characterization was performed, including release kinetics, Staphylococcus aureus antibacterial/antibiofilm activities and cytocompatibility. The results demonstrated the feasibility of the vancomycin-loaded 3D-printed PLA-HA scaffolds as drug-releasing vehicles with significant antibacterial effects for the three methodologies. In relation to the drug release kinetics, the (1) dip- and (2) drop-coating methodologies achieved burst release (first 60 min) of around 80-90% of the loaded vancomycin, followed by a slower release of the remaining drug for up to 48 h, while the (3) 3D printing presented an extended release beyond 7 days as the polymer degraded. The cytocompatibility of the vancomycin-loaded scaffolds was also confirmed.

Published

2023

6. Using machine learning to link the influence of transferred Agrobacterium rhizogenes genes to the hormone profile and morphological traits in Centella asiatica hairy roots.

Author

Alcalde MA, Müller M, Munné-Bosch S, Landín M, Gallego PP, Bonfill M, Palazon J, and Hidalgo-Martinez D

Abstract

Hairy roots are made after the integration of a small set of genes from Agrobacterium rhizogenes in the plant genome. Little is known about how this small set is linked to their hormone profile, which determines development, morphology, and levels of secondary metabolite production. We used C. asiatica hairy root line cultures to determine the putative links between the rol and aux gene expressions with morphological traits, a hormone profile, and centelloside production. The results obtained after 14 and 28 days of culture were processed via multivariate analysis and machine-learning processes such as random forest, supported vector machines, linear discriminant analysis, and neural networks. This allowed us to obtain models capable of discriminating highly productive root lines from their levels of genetic expression ( rol and aux genes) or from their hormone profile. In total, 12 hormones were evaluated, resulting in 10 being satisfactorily detected. Within this set of hormones, abscisic acid (ABA) and cytokinin isopentenyl adenosine (IPA) were found to be critical in defining the morphological traits and centelloside content. The results showed that IPA brings more benefits to the biotechnological platform. Additionally, we determined the degree of influence of each of the evaluated genes on the individual hormone profile, finding that aux1 has a significant influence on the IPA profile, while the rol genes are closely linked to the ABA profile. Finally, we effectively verified the gene influence on these two specific hormones through feeding experiments that aimed to reverse the effect on root morphology and centelloside content., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2022 Alcalde, Müller, Munné-Bosch, Landín, Gallego, Bonfill, Palazon and Hidalgo-Martinez.)

Published

2022

7. Shoot tip necrosis of in vitro plant cultures: a reappraisal of possible causes and solutions.

Author

Teixeira da Silva JA, Nezami-Alanagh E, Barreal ME, Kher MM, Wicaksono A, Gulyás A, Hidvégi N, Magyar-Tábori K, Mendler-Drienyovszki N, Márton L, Landín M, Gallego PP, Driver JA, and Dobránszki J

Subjects

Antioxidants chemistry, Antioxidants pharmacology, Boron metabolism, Boron pharmacology, Calcium metabolism, Calcium pharmacology, Cell Death, Genotype, Necrosis, Nitrogen metabolism, Plant Growth Regulators metabolism, Plant Growth Regulators pharmacology, Plant Shoots cytology, Plant Shoots drug effects, Culture Media chemistry, Culture Media pharmacology, Plant Shoots growth & development, Tissue Culture Techniques methods

Abstract

Main Conclusion: Shoot tip necrosis is a physiological condition that negatively impacts the growth and development of in vitro plant shoot cultures across a wide range of species. Shoot tip necrosis is a physiological condition and disorder that can arise in plantlets or shoots in vitro that results in death of the shoot tip. This condition, which can spread basipetally and affect the emergence of axillary shoots from buds lower down the stem, is due to the cessation of apical dominance. STN can occur at both shoot multiplication and rooting stages. One of the most common factors that cause STN is nutrient deficiency or imbalance. Moreover, the presence or absence of plant growth regulators (auxins or cytokinins) at specific developmental stages may impact STN. The cytokinin to auxin ratio within an in vitro plant can be modified by varying the concentration of cytokinins used in the culture medium. The supply of nutrients to in vitro shoots or plantlets might also affect their hormonal balance, thus modifying the occurrence of STN. High relative humidity within culture vessels and hyperhydricity are associated with STN. An adequate supply of calcium as the divalent cation (Ca 2+ ) can hinder STN by inhibiting the accumulation of phenolic compounds and thus programmed cell death. Moreover, the level of Ca 2+ affects auxin transport and ethylene production, and higher ethylene production, which can occur as a result of high relative humidity in or poor ventilation of the in vitro culture vessel, induces STN. High relative humidity can decrease the mobility of Ca 2+ within a plant, resulting in Ca 2+ deficiency and STN. STN of in vitro shoots or plantlets can be halted or reversed by altering the basal medium, mainly the concentration of Ca 2+ , adjusting the levels of auxins or cytokinins, or modifying culture conditions. This review examines the literature related to STN, seeks to discover the associated factors and relations between them, proposes practical solutions, and attempts to better understand the mechanism(s) underlying this condition in vitro.

Published

2020

8. Technologies and Formulation Design of Polysaccharide-Based Hydrogels for Drug Delivery.

Author

Auriemma G, Russo P, Del Gaudio P, García-González CA, Landín M, and Aquino RP

Subjects

Chemistry, Pharmaceutical methods, Drug Carriers chemistry, Drug Delivery Systems methods, Humans, Porosity, Technology, Pharmaceutical methods, Hydrogels chemistry, Polysaccharides chemistry

Abstract

Polysaccharide-based hydrogel particles (PbHPs) are very promising carriers aiming to control and target the release of drugs with different physico-chemical properties. Such delivery systems can offer benefits through the proper encapsulation of many drugs (non-steroidal and steroidal anti-inflammatory drugs, antibiotics, etc) ensuring their proper release and targeting. This review discusses the different phases involved in the production of PbHPs in pharmaceutical technology, such as droplet formation (SOL phase), sol-gel transition of the droplets (GEL phase) and drying, as well as the different methods available for droplet production with a special focus on prilling technique. In addition, an overview of the various droplet gelation methods with particular emphasis on ionic cross-linking of several polysaccharides enabling the formation of particles with inner highly porous network or nanofibrillar structure is given. Moreover, a detailed survey of the different inner texture, in xerogels, cryogels or aerogels, each with specific arrangement and properties, which can be obtained with different drying methods, is presented. Various case studies are reported to highlight the most appropriate application of such systems in pharmaceutical field. We also describe the challenges to be faced for the breakthrough towards clinic studies and, finally, the market, focusing on the useful approach of safety-by-design (SbD)., Competing Interests: The authors declare no conflict of interest.

Published

2020

9. Machine Learning Technology Reveals the Concealed Interactions of Phytohormones on Medicinal Plant In Vitro Organogenesis.

Author

García-Pérez P, Lozano-Milo E, Landín M, and Gallego PP

Subjects

Benzyl Compounds pharmacology, Indoleacetic Acids pharmacology, Kalanchoe drug effects, Kalanchoe growth & development, Plants, Medicinal drug effects, Purines pharmacology, Machine Learning, Organogenesis drug effects, Plant Growth Regulators pharmacology, Plants, Medicinal growth & development

Abstract

Organogenesis constitutes the biological feature driving plant in vitro regeneration, in which the role of plant hormones is crucial. The use of machine learning (ML) technology stands out as a novel approach to characterize the combined role of two phytohormones, the auxin indoleacetic acid (IAA) and the cytokinin 6-benzylaminopurine (BAP), on the in vitro organogenesis of unexploited medicinal plants from the Bryophyllum subgenus. The predictive model generated by neurofuzzy logic, a combination of artificial neural networks (ANNs) and fuzzy logic algorithms, was able to reveal the critical factors affecting such multifactorial process over the experimental dataset collected. The rules obtained along with the model allowed to decipher that BAP had a pleiotropic effect on the Bryophyllum spp., as it caused different organogenetic responses depending on its concentration and the genotype, including direct and indirect shoot organogenesis and callus formation. On the contrary, IAA showed an inhibiting role, restricted to indirect shoot regeneration. In this work, neurofuzzy logic emerged as a cutting-edge method to characterize the mechanism of action of two phytohormones, leading to the optimization of plant tissue culture protocols with high large-scale biotechnological applicability., Competing Interests: The authors declare no conflict of interest.

Published

2020

10. Combining Medicinal Plant In Vitro Culture with Machine Learning Technologies for Maximizing the Production of Phenolic Compounds.

Author

García-Pérez P, Lozano-Milo E, Landín M, and Gallego PP

Abstract

We combined machine learning and plant in vitro culture methodologies as a novel approach for unraveling the phytochemical potential of unexploited medicinal plants . In order to induce phenolic compound biosynthesis, the in vitro culture of three different species of Bryophyllum under nutritional stress was established. To optimize phenolic extraction, four solvents with different MeOH proportions were used, and total phenolic content (TPC), flavonoid content (FC) and radical-scavenging activity (RSA) were determined. All results were subjected to data modeling with the application of artificial neural networks to provide insight into the significant factors that influence such multifactorial processes. Our findings suggest that aerial parts accumulate a higher proportion of phenolic compounds and flavonoids in comparison to roots. TPC was increased under ammonium concentrations below 15 mM, and their extraction was maximum when using solvents with intermediate methanol proportions (55-85%). The same behavior was reported for RSA, and, conversely, FC was independent of culture media composition, and their extraction was enhanced using solvents with high methanol proportions (>85%). These findings confer a wide perspective about the relationship between abiotic stress and secondary metabolism and could serve as the starting point for the optimization of bioactive compound production at a biotechnological scale., Competing Interests: The authors declare no conflict of interest.

Published

2020

11. Current Stage of Marine Ceramic Grafts for 3D Bone Tissue Regeneration.

Author

Diaz-Rodriguez P, López-Álvarez M, Serra J, González P, and Landín M

Subjects

Allografts classification, Animals, Biocompatible Materials, Bone Regeneration, Bone and Bones, Heterografts classification, Humans, Aquatic Organisms chemistry, Bone Transplantation methods, Ceramics therapeutic use

Abstract

Bioceramic scaffolds are crucial in tissue engineering for bone regeneration. They usually provide hierarchical porosity, bioactivity, and mechanical support supplying osteoconductive properties and allowing for 3D cell culture. In the case of age-related diseases such as osteoarthritis and osteoporosis, or other bone alterations as alveolar bone resorption or spinal fractures, functional tissue recovery usually requires the use of grafts. These bone grafts or bone void fillers are usually based on porous calcium phosphate grains which, once disposed into the bone defect, act as scaffolds by incorporating, to their own porosity, the intergranular one. Despite their routine use in traumatology and dental applications, specific graft requirements such as osteoinductivity or balanced dissolution rate are still not completely fulfilled. Marine origin bioceramics research opens the possibility to find new sources of bone grafts given the wide diversity of marine materials still largely unexplored. The interest in this field has also been urged by the limitations of synthetic or mammalian-derived grafts already in use and broadly investigated. The present review covers the current stage of major marine origin bioceramic grafts for bone tissue regeneration and their promising properties. Both products already available on the market and those in preclinical phases are included. To understand their clear contribution to the field, the main clinical requirements and the current available biological-derived ceramic grafts with their advantages and limitations have been collected.

Published

2019

12. Computer-based tools provide new insight into the key factors that cause physiological disorders of pistachio rootstocks cultured in vitro.

Author

Nezami-Alanagh E, Garoosi GA, Landín M, and Gallego PP

Subjects

Artificial Intelligence, Fuzzy Logic, In Vitro Techniques, Pistacia drug effects, Plant Leaves drug effects, Plant Leaves growth & development, Plant Roots drug effects, Plant Roots growth & development, Plant Shoots drug effects, Plant Shoots growth & development, Culture Media chemistry, Edetic Acid pharmacology, Pistacia growth & development

Abstract

During the in vitro culture of plants some physiological disorders caused major problems that have been associated with culture media composition. The objective of this study was to better understand the abnormal physiological response of two pistachio rootstocks to changes in culture media ingredients. On this purpose, two computer-based tools were employed: design of experiment (DOE) and neurofuzzy logic. DOE was employed to generate a five-dimensional IV-design spaces allowing to reduce the number of treatments from 6,250 to 61. The second one, an artificial intelligence (AI) tool, neurofuzzy logic, was used to understand the cause-effect relationships between the factors studied (25) and seven physiological disorders including shoot-tip necrosis (STN), leaf necrosis (LN), leaf color (LC), basal callus (BC) formation, shoot fasciation (SF), hyperhydricity and epinasty, typically described during pistachio in vitro culture. Four out of the seven disorders were successfully modeled, being significantly affected by a limited number of factors. STN and BC were significantly affected by the concentration of EDTA - . However, while a low concentration of EDTA - reduces the STN, promotes BC. LN and LC were strongly alleviated by high amounts of thiamine-HCl. Undoubtedly, the results demonstrate the importance of recording and using data related to physiological disorders along with growth parameters when developing suitable culture media for plant tissues. The computer-based tools have been useful to: i) well sample experimental design; ii) reduce the final number of treatments and the experimental work; iii) identify the key factors affecting each disorder; iv) get insight about the causes that promote the appearance of physiological disorders. Our findings demonstrate that the recently AI designed POM media, although not optimal, is the most suitable (favouring growth and limiting physiological abnormalities) media for in vitro culture of pistachio compared to those media, currently used.

Published

2019

13. Combining DOE With Neurofuzzy Logic for Healthy Mineral Nutrition of Pistachio Rootstocks in vitro Culture.

Author

Nezami-Alanagh E, Garoosi GA, Landín M, and Gallego PP

Abstract

The aim of this study was to determine the effects of Murashige and Skoog (MS) salts on optimal growth of two pistachio rootstocks, P. vera cv. "Ghazvini" and "UCB1" using design of experiments (DOE) and artificial intelligence (AI) tools. MS medium with 14 macro-and micro-elements was used as base point and its concentration varied from 0 to 5 × MS concentrations. Design of experiments (DOE) software was used to generate a five-dimensional design space by categorizing MS salts into five independent factors (NH 4 NO 3 , KNO 3 , mesos, micros and iron), reducing the experimental design space from 3,125 to just 29 treatments. Typical plant growth parameters such as shoot quality (SQ), proliferation rate (PR), shoot length (SL), and some physiological disorders including shoot-tip necrosis (STN) and callus formation at the base of explants (BC) were evaluated for each treatment. The results were successfully modeled using neurofuzzy logic software. The model delivered new insights, by different sets of "IF-THEN" rules, pinpointing the key role of some ion interactions ( SO 4 2 - × Cl - , K + × SO 4 2 - × EDTA - , and Fe 2+ × Cu 2+ × NO 3 - ) for SQ, PR, and SL, whilst physiological disorders (STN and BC) were governed mainly by independent ions as Fe 2+ and EDTA - , respectively. In our opinion, the methodology and results obtained in this study is extremely useful to understand the effect of mineral nutrients on pistachio in vitro culture, through discovering new complex interactions among macro-and micro-elements which can be implemented to design new media of plant tissue culture and improve healthy plant micropropagation for any plant species.

Published

2018

14. A novel method for the production of core-shell microparticles by inverse gelation optimized with artificial intelligent tools.

Author

Rodríguez-Dorado R, Landín M, Altai A, Russo P, Aquino RP, and Del Gaudio P

Subjects

Capsules, Chemistry, Pharmaceutical methods, Drug Compounding, Emulsions, Equipment Design, Fuzzy Logic, Gels, Glucuronic Acid chemistry, Hexuronic Acids chemistry, Hydrophobic and Hydrophilic Interactions, Microspheres, Neural Networks, Computer, Sunflower Oil chemistry, Technology, Pharmaceutical methods, Alginates chemistry, Artificial Intelligence, Calcium Chloride chemistry, Sunflower Oil administration & dosage

Abstract

Numerous studies have been focused on hydrophobic compounds encapsulation as oils. In fact, oils can provide numerous health benefits as synergic ingredient combined with other hydrophobic active ingredients. However, stable microparticles for pharmaceutical purposes are difficult to achieve when commonly techniques are used. In this work, sunflower oil was encapsulated in calcium-alginate capsules by prilling technique in co-axial configuration. Core-shell beads were produced by inverse gelation directly at the nozzle using a w/o emulsion containing aqueous calcium chloride solution in sunflower oil pumped through the inner nozzle while an aqueous alginate solution, coming out from the annular nozzle, produced the beads shell. To optimize process parameters artificial intelligence tools were proposed to optimize the numerous prilling process variables. Homogeneous and spherical microcapsules with narrow size distribution and a thin alginate shell were obtained when the parameters as w/o constituents, polymer concentrations, flow rates and frequency of vibration were optimized by two commercial software, FormRules® and INForm®, which implement neurofuzzy logic and Artificial Neural Networks together with genetic algorithms, respectively. This technique constitutes an innovative approach for hydrophobic compounds microencapsulation., (Copyright © 2018 Elsevier B.V. All rights reserved.)

Published

2018

15. Fabrication of Zn-Sr-doped laser-spinning glass nanofibers with antibacterial properties.

Author

Echezarreta-López MM, de Miguel T, Quintero F, Pou J, and Landín M

Abstract

The morphology and dimensions of bioactive materials are essential attributes to promote tissue culture. Bioactive materials with nanofibrous structure have excellent potential to be used as bone-defect fillers, since they mimic the collagen in the extracellular matrix. On the other hand, bioactive glasses with applications in regenerative medicine may present antibacterial properties, which depend on glass composition, concentration and the microorganisms tested. Likewise, their morphology may influence their antibacterial activity too. In the present work, the laser-spinning technique was used to produce bioactive glass nanofibers of two different compositions: 45S5 Bioglass® and ICIE16M, bioactive glass doped with zinc and strontium. Their antibacterial activity against Staphylococcus aureus was tested by culturing them in dynamic conditions. Bacterial growth index profiles during the first days of experiment can be explained by the variations in the pH values of the media. The bactericidal effect of the doped nanofibers at longer times is justified by the release of zinc and strontium ions. Cytotoxicity was analyzed by means of cell viability tests performed with BALB/3T3 cell line.

Published

2017